Melanocortin signaling in the CNS directly regulates circulating cholesterol.

Cholesterol circulates in the blood in association with triglycerides and other lipids, and elevated blood low-density lipoprotein cholesterol carries a risk for metabolic and cardiovascular disorders, whereas high-density lipoprotein (HDL) cholesterol in the blood is thought to be beneficial. Circulating cholesterol is the balance among dietary cholesterol absorption, hepatic synthesis and secretion, and the metabolism of lipoproteins by various tissues. We found that the CNS is also an important regulator of cholesterol in rodents. Inhibiting the brain's melanocortin system by pharmacological, genetic or endocrine mechanisms increased circulating HDL cholesterol by reducing its uptake by the liver independent of food intake or body weight. Our data suggest that a neural circuit in the brain is directly involved in the control of cholesterol metabolism by the liver.

Class B type I scavenger receptor is responsible for the high affinity cholesterol binding activity of intestinal brush border membrane vesicles.

Recent studies have documented the importance of Niemann-Pick C1-like 1 protein (NPC1L1), a putative physiological target of the drug ezetimibe, in mediating intestinal cholesterol absorption. However, whether NPC1L1 is the high affinity cholesterol binding protein on intestinal brush border membranes is still controversial. In this study, brush border membrane vesicles (BBMV) from wild type and NPC1L1-/- mice were isolated and assayed for micellar cholesterol binding in the presence or absence of ezetimibe. Results confirmed the loss of the high affinity component of cholesterol binding when wild type BBMV preparations were incubated with antiserum against the class B type 1 scavenger receptor (SR-BI) in the reaction mixture similar to previous studies. Subsequently, second order binding of cholesterol was observed with BBMV from wild type and NPC1L1-/- mice. The inclusion of ezetimibe in these in vitro reaction assays resulted in the loss of the high affinity component of cholesterol interaction. Surprisingly, BBMVs from NPC1L1-/- mice maintained active binding of cholesterol. These results documented that SR-BI, not NPC1L1, is the major protein responsible for the initial high affinity cholesterol ligand binding process in the cholesterol absorption pathway. Additionally, ezetimibe may inhibit BBM cholesterol binding through targets such as SR-BI in addition to its inhibition of NPC1L1.

Effects of chenodeoxycholic acid and deoxycholic acid on cholesterol absorption and metabolism in humans.

Quantitative and qualitative differences in intralumenal bile acids may affect cholesterol absorption and metabolism. To test this hypothesis, 2 cross-over outpatient studies were conducted in adults with apo-A IV 1/1 or apo-E 3/3 genotypes. Study 1 included 11 subjects 24 to 37 years of age, taking 15 mg/kg/day chenodeoxycholic acid (CDCA) or no bile acid for 20 days while being fed a controlled diet. Study 2 included 9 adults 25 to 38 years of age, taking 15 mg/kg/day deoxycholic acid (DCA) or no bile acid, following the same experimental design and procedures as study 1. CDCA had no effect on plasma lipid concentrations, whereas DCA decreased (P < 0.05) plasma high-density lipoprotein (HDL)-cholesterol and tended to decrease (P = 0.15) low-density lipoprotein (LDL)-cholesterol. CDCA treatment enriched (P < 0.0001) bile with CDCA and increased cholesterol concentration in micelles, whereas meal-stimulated bile acid concentrations were decreased. DCA treatment enriched (P < 0.0001) bile with DCA and tended to increase intralumenal cholesterol solubilized in micelles (P = 0.06). No changes were found in cholesterol absorption, free cholesterol fractional synthetic rate (FSR), or 3-hydroxy-3 methylglutaryl (HMG) CoA reductase and LDL receptor messenger ribonucleic acid (mRNA) levels after CDCA treatment. DCA supplementation tended to decrease cholesterol absorption and reciprocally increase FSR and HMG CoA reductase and LDL receptor mRNA levels. Results of these 2 studies suggest that the solubilization of cholesterol in the intestinal micelles is not a rate-limiting step for its absorption.

Yolk sac cholesteryl ester secretion rates can be manipulated in the Golden Syrian hamster: effect of yolk sac cholesterol concentrations.

The yolk sac is one of two extra-embryonic fetal tissues that separates the fetal and maternal circulations. The yolk sac can secrete lipoprotein particles to the vitelline vessels, which supply yolk sac-derived nutrients to the embryo. The amount and composition of lipoproteins secreted from the rat yolk sac can be manipulated by fatty acid content and gestational age. The goals of the current studies were to determine, first, if tissue cholesterol concentration could mediate cholesterol secretion rate from the yolk sac and, second, if some of the secreted cholesterol could be derived from the maternal circulation. Golden Syrian hamsters were fed 2% added cholesterol to increase the yolk sac cholesterol concentration. Yolk sac explants secreted similar amounts of triglyceride and apolipoproteins B and E into the media regardless of yolk sac cholesterol concentration. In contrast, yolk sacs with greater cholesterol concentrations secreted 2.3-fold more cholesterol into the media as compared to control yolk sacs; the increase was found mostly as cholesteryl ester. At least part of the secreted cholesterol was maternally derived. These data demonstrate that yolk sac cholesterol concentration influences cholesterol secretion rates, and that at least some of the cholesterol secreted originates from the maternal circulation.

Cholic acid supplementation enhances cholesterol absorption in humans.

BACKGROUND & AIMS: Qualitative and quantitative changes in intralumenal bile acid composition may alter cholesterol absorption and synthesis and low-density lipoprotein (LDL) receptor expression. The role of cholic acid (CA) in cholesterol absorption in humans remains unclear and, thus, was examined in the current study. METHODS: In a crossover design outpatient study, 12 adults aged 24-36 years took 15 mg/kg/day (CA) or no bile acid supplement (control) while being fed a controlled diet (AHA heart-healthy diet). A liquid meal of defined composition was given on day 14 of the diet, and lumenal samples were collected. Thereafter, cholesterol absorption and cholesterol fractional synthetic rate (FSR) were assessed by stable isotopic methods from days 16 to 20. RESULTS: With CA treatment, bile was enriched significantly with CA (P < 0.0004) to 60.2% +/- 2.4% (mean +/- SEM) compared with 43.3% +/- 2.4% for controls. CA plus diet treatment significantly increased (P = 0.013) cholesterol absorption (72.6% +/- 2.9%) compared with diet treatment alone (60.4% +/- 2.9%). Percentage micellar cholesterol was increased by CA plus diet treatment vs. diet alone after meal ingestion (P = 0.004). Plasma total and high-density lipoprotein (HDL) and LDL cholesterol was unchanged with CA treatment. CONCLUSIONS: Thus, enrichment in lumenal bile with CA results in an increase in cholesterol absorption, an effect potentially mediated by enhanced cholesterol solubilization in micelles.

Effect of ursodeoxycholic acid on cholesterol absorption and metabolism in humans.

Qualitative and quantitative changes in intraluminal bile acid composition may alter cholesterol absorption and synthesis and LDL receptor expression. In a randomized crossover design outpatient study, 12 adults aged 24-36 years took 15 mg/kg/day ursodeoxycholic acid (UDCA) or no bile acid supplement (control) for 20 days while being fed a controlled diet (AHA Step II). A liquid meal of defined composition was then given and luminal samples collected. Cholesterol absorption and cholesterol fractional synthetic rate (FSR) were assessed by stable isotopic methods. With UDCA treatment, bile was enriched significantly (P < 0.0001) to 40.6 +/- 2.6% (mean +/- SEM) compared with 2.2 +/- 2.6% for controls. Regardless, plasma total, HDL, and LDL cholesterol were unchanged with UDCA treatment. Intraluminal cholesterol solubilized in the aqueous phase during the entire collection was decreased (P = 0.012) in UDCA-treated subjects (101.0 +/- 7.2 mg/ml/120 min) compared with controls (132.5 +/- 7.2 mg/ml/120 min.). Percent micellar cholesterol was increased in UDCA-treated versus controls after meal ingestion. No changes were found in cholesterol absorption, FSR, or LDL receptor mRNA with UDCA treatment compared with controls. Thus, despite marked enrichment in luminal bile with UDCA and decreased cholesterol solubilization, no differences in cholesterol absorption or metabolism are found when diet and genetic differences in absorption are carefully controlled.

Separation of micelles and vesicles within lumenal aspirates from healthy humans: solubilization of cholesterol after a meal.

Understanding the physico-chemical relationship of lumenal lipids to one another is critical when elucidating the mechanism of components known to impact cholesterol absorption. Presently, there are no studies that describe the proportion of cholesterol carried as micelles or vesicles within human lumenal contents. Part of the reason for the scarceness of data is because of the lack of appropriate methodology required for reproducible sample collection and analysis. Thus, the object of the present studies was to develop a method to measure the amount of cholesterol carried as micelles or vesicles in human lumenal samples. The method includes the collection of lumenal samples from the ligament of Trietz through a Fredrick Miller tube, separation of the aqueous subphase from the nondigested lipids, separation of micelles and vesicles on Sepharose 4B columns within 48 h of collection using elution buffers consisting of the intermicellar bile acid composition, and finally quantitation of cholesterol eluted off of the columns. The distribution of cholesterol between micelles and vesicles obtained under different concentrations of bile acids and various lipids was comparable to results obtained from phase diagrams using the lumenal molar percentages of lipids obtained from the same samples.